Air-Gun Simulated Training Weapon

ABSTRACT

A non-lethal, air-gun training weapon that is used to realistically simulate the behavior of a live firearm. The non-lethal, air-gun training weapon provides an air-gun to simulate the weight and feel of a live firearm. A magazine that attaches to the air-gun houses a gas container, which feeds compressed gas into the air-gun. The release of compressed gas actuates a laser assembly and a bolt both housed within the air-gun. The laser assembly allows users to track dry-fired shots, while movement of the bolt simulates the recoil of a live firearm. An electromechanical system housed within the magazine features a transceiver that is capable of wirelessly transmitting and receiving information from an external computer system. The electromechanical assembly also includes a jamming mechanism that can be activated by a controller board in order to simulate an empty clip or jammed weapon. The jamming mechanism can be manually or remotely reset.

The current application claims a priority to the U.S. Provisional Patentapplication Ser. No. 61/695,084 filed on Aug. 30, 2012.

FIELD OF THE INVENTION

The present invention relates generally to an apparatus used for virtualfirearms training. More specifically, the present invention is an airgun that is able to realistically simulate targeted gunfire using alaser, weapon recoil, trigger activity, ammunition count, and weaponjamming.

BACKGROUND OF THE INVENTION

Law enforcement and military training often place trainees intosituations that require quick visual and mental assessment of thesituation as well as an appropriate response with a weapon. Trainees areoften subjected to adverse situations to test their abilities toeffectively react. While physically they closely resemble their truefirearm counterparts, air guns are usually not suitable for providing arealistic simulation of live firearm use. It is difficult to simulatethe intricate mechanics of firearm use such as unexpected weapon jams infirefights and realistic weapon recoil. Thus, there are many problemswith realistically presenting these kinds of situations to a traineeusing air guns. It is often necessary to utilize The Bureau of Alcohol,Tobacco, Firearms, and Explosives (ATF) certified non-gun(de-militarized) firearms retrofitted with laser and recoil kits.However, there is an increased security risk with the distribution andusage of ATF certified non-gun alternatives as these are real firearmsthat have been demilitarized whereas air guns have always been toys, notcreated from real weapon molds, only modeled after real firearms.Although ATF certified non-guns reasonably simulate the recoil of afirearm loaded with live ammunition, they are still treated as realweapons, locked in secure storage containers when not in use. Thisrequires a higher level of logistics and weapon tracking that wouldotherwise be unnecessary with air guns. Alternatively, an air gun isconsidered a toy by the ATF and therefore does not require enhancedsecurity when not in use. The present invention seeks to address theproblems faced when attempting to provide a realistic shootingexperience with air guns while circumventing the security requirementsbrought about by other solutions such as ATF certified non-guns.

It is therefore the object of the present invention to provide anon-lethal, air-gun training weapon for realistically simulating thebehavior of a live firearm. The present invention provides an air-gun tosimulate the weight and feel of a live firearm. A laser assembly housedwithin the air-gun allows users to track their dry fired shots in lieuof using air gun ammunition such as pellets. Compressed air or gasstored in a gas container is provided to the air gun in a manner normalto an air gun. The gas container is positioned within a magazine tofurther simulate a live firearm. Upon firing the non-lethal, air-guntraining weapon, the sudden release of compressed air or other gas intothe air-gun actuates a bolt through a bolt chamber towards the stock atthe rear of the air-gun. This allows the user to reasonably simulate therecoil generated from the momentum of a real firearm. Anelectromechanical system housed within the magazine features atransceiver that is capable of wirelessly transmitting and receivinginformation from an external computer system. This allows thenon-lethal, air-gun training weapon to track the user's trigger pullswhich in turn allows the system to track ammunition count as well.Another example would involve the computer receiving information aboutthe tilt and cant of an air gun from sensors that are included in theelectromechanical magazine. The external computer system is capable ofsending a command to jam the air-gun training weapon to force the userto rectify the problem before continuing to fire. When the exhaustion ofammunition or weapon jamming has been rectified, the user may beginshooting again. These combined features of the present invention providethe air gun user with realistic situations that may arise during the useof a real firearm.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a right side view of the present invention.

FIG. 2 is a right side sectional view of the receiver, magazine, andelectromechanical assembly.

FIG. 3 is a right side sectional view of the receiver showing the gasrelease pin engaging the gas release valve.

FIG. 4 is a right side sectional view of the receiver showing thejamming rod engaging the bolt.

FIG. 5 is a right side sectional view showing the laser assembly beingpositioned within the barrel of the air-gun.

FIG. 6 is a right side sectional view of the electromechanical assemblyhoused within the magazine.

FIG. 7 is a right side sectional view of the magazine having a gasrefill valve in fluid communication with the gas container.

FIG. 8 is a perspective view of the laser assembly.

FIG. 9 is a right side sectional view of the laser assembly.

FIG. 10 is a right side sectional view of the laser assembly having alaser battery.

FIG. 11 is a diagram depicting the transceiver, jamming device, and boltsensor being electronically connected to the controller board.

FIG. 12 is a diagram depicting the electrical connections of theelectromechanical assembly and the laser assembly in a one batterysystem.

FIG. 13 is a diagram depicting the electrical connections of theelectromechanical assembly in a two battery system.

FIG. 14 is a diagram depicting the electrical connections of the laserassembly in a two battery system.

DETAIL DESCRIPTIONS OF THE INVENTION

All illustrations of the drawings are for the purpose of describingselected versions of the present invention and are not intended to limitthe scope of the present invention.

The present invention is a non-lethal, air-gun training weapon that iscapable of realistically simulating targeted gunfire, weapon recoil,trigger 161 activity, ammunition count, and weapon jamming. Thenon-lethal, air-gun training weapon is created as a toy, therefore, thenon-lethal, air-gun training weapon can never be used as a real firearm.The non-lethal, air-gun training weapon comprises an air-gun 1, amagazine 2, a laser assembly 3 and an electromechanical assembly 4. Theair-gun 1 serves as the main body of the non-lethal, air-gun trainingweapon and acts to provide the same weight and feel of a real firearm.The laser assembly 3 is positioned within the air-gun 1, while theelectromechanical assembly 4 is housed within the magazine 2. Themagazine 2 is removably attached to the air-gun 1 such that the magazine2 may be detached in order to simulate the reloading of a weapon.

In reference to FIG. 1-2, the air-gun 1 comprises a receiver 11, abarrel 12, a bolt 13, a bolt chamber 14, a gas channel 15, and a firingmechanism 16. The receiver 11 is the central body of the air-gun 1 andthe component to which the magazine 2 is attached via a port along thebottom of the receiver 11. The gas channel 15 traverses into thereceiver 11 through this port and into the bolt chamber 14. The firingmechanism 16 is positioned within the receiver 11 adjacent to the port.In the preferred embodiment of the present invention, the firingmechanism 16 is similar to that of a traditional firearm and comprises atrigger 161, a hammer 162, and a gas release pin 163. The trigger 161traverses out of the receiver 11, such that the trigger 161 may beengaged by a user. Through the hammer 162, the trigger 161 isoperatively coupled to the gas release pin 163. The hammer 162 is springloaded and is held in a compressed state through a mechanical couplingto the trigger 161. When the trigger 161 is pulled back, the hammer 162is released from the compressed state and pivots within the receiver 11to engage the gas release pin 163. The gas release pin 163 is slidablypositioned within the receiver 11 such that when the gas release pin 163is engaged by the hammer 162, the gas release pin 163 is pushed forwardtowards the port in the receiver 11 designed to retain the magazine 2.

The barrel 12 is adjacently connected to the front of the receiver 11and provides a channel in which the laser assembly 3 is positioned. Thebarrel 12 is positioned such that it is concentric with the bolt chamber14, as shown in FIG. 5. The bolt chamber 14 is a cylindrical channelthat traverses into the receiver 11. The bolt 13 is spring loaded and isslidably positioned within the bolt chamber 14. When the non-lethal,air-gun training weapon is fired, the bolt 13 is forced towards the backof the receiver 11 in order to simulate the recoil of a real firearm. Asthe bolt 13 moves towards the back of the receiver 11, a bolt 13 springis compressed, which then decompresses to return the bolt 13 back to anunfired position. As the bolt 13 traverses along the bolt chamber 14towards the back of the receiver 11, the bolt 13 also acts to reset thehammer 162.

In reference to FIG. 6, the magazine 2 comprises a magazine casing 21, agas container 22, a gas release valve 23, and a gas release vent. Thegas container 22 is a closed cylindrical tube positioned within themagazine casing 21. The gas container 22 may be permanently connectedwithin the magazine casing 21 or removably attached within thecontainer, such that the gas container 22 can be replaced, refilledexternally, etc. The gas release valve 23 is positioned into themagazine casing 21, such that the gas release valve 23 can be actuatedthrough the side of the magazine casing 21. The gas release valve 23 iscoupled to the gas container 22 and is used to regulate the release ofcompressed gas from the gas container 22. When the magazine casing 21 isattached to the receiver 11 via the port at the bottom of the receiver11, the gas container 22 is in fluid communication with the gas channel15 through the gas release valve 23. In this way, the gas container 22is pneumatically coupled to both the laser assembly 3 and the bolt 13through the gas channel 15 and the bolt chamber 14.

When the non-lethal, air-gun training weapon is fired, the gas releasepin 163 engages the gas release valve 23 as shown in FIG. 3, which inturn opens the gas container 22, allowing compressed gas to travelthrough the gas channel 15 and into the bolt chamber 14. The force ofthe compressed gas then actuates the laser assembly 3 and sets the bolt13 in motion within the bolt chamber 14. The gas release valve 23 isspring loaded, such that when the hammer 162 is reset by the bolt 13,the gas release valve 23 closes the gas container 22 and forces the gasrelease pin 163 back into the unfired position. As the bolt 13 traversesalong the bolt chamber 14, the compressed gas is vented through openingsin the bolt chamber 14, when the bolt cycles far enough to release thegas and reset the trigger, and openings in the receiver 11 in order todepressurize the bolt chamber 14.

In reference to FIG. 7, if the gas container 22 is designed to bepermanently positioned within the magazine casing 21, then the magazine2 further comprises a gas refill valve 24. Similar to the gas releasevalve 23, the gas refill valve 24 is positioned into the magazine casing21, such that the gas refill valve 24 can be accessed through the top,bottom, or one of the sides of the magazine casing 21. The gas refillvalve 24 is in fluid communication with the gas container 22. The gasrefill valve 24 is a one way valve that when open allows the gascontainer 22 to be filled with compressed gas.

In reference to FIG. 6, the electromechanical assembly 4 is contained bythe magazine 2 of the air-gun 1 and comprises a transceiver 41, acontroller board 42, a jamming device 43, a bolt sensor 44, and abattery 45. The transceiver 41, the controller board 42, and the battery45 are positioned within the magazine casing 21, while the bolt sensor44 is positioned into the top of the magazine casing 21 that engages thereceiver 11 of the air-gun 1. The battery 45 supplies current to powerthe other components of the electromechanical assembly 4 and, as such,the transceiver 41, the controller board 42, the jamming device 43, andthe bolt sensor 44 are electrically connected to the battery 45, asdepicted in FIG. 12-13. In the preferred embodiment of the presentinvention, the battery 45 is rechargeable and can be charged through apair of leads positioned on the bottom of the magazine casing 21. If thebattery 45 is not rechargeable, then an access panel may be built intothe magazine casing 21 in order to remove and replace the battery 45.

The controller board 42 is a programmable chip or similar device that iselectronically connected to the transceiver 41, the jamming device 43,and the bolt sensor 44, as depicted in FIG. 11. The transceiver 41 iscapable of wirelessly transmitting and receiving data to and from anexternal computer system. Signals received by the controller board 42from the transceiver 41 and/or bolt sensor 44 are analyzed and used toinitiate activation of the jamming device 43. When the user pulls thetrigger 161 of the air-gun 1, the bolt sensor 44 detects the movement ofthe bolt 13 within the bolt chamber 14 in order to determine thesimulation of a shot being fired. If the trigger 161 is pulled and thebolt sensor 44 is able to detect the bolt 13 within the cycle time ofthe bolt 13, then the controller board 42 is able to determine that ashot has been fired. The bolt sensor 44 can be any type of sensor, suchas a magnetic or optical sensor. If a magnetic sensor is utilized, thena magnet is also connected to the bolt 13.

In the preferred embodiment of the present invention, data is constantlytransferred bi-directionally between the controller board 42 and theexternal computer system via the transceiver 41. The signal from thebolt sensor 44 is sent to the controller board 42 and then transmittedto the external computer system via the transceiver 41. The externalcomputer system can then record the number of simulated laser roundsfired by the non-lethal, air-gun training weapon. When the number ofsimulated laser rounds fired reaches a predetermined limit, the externalcomputer system transmits a signal to the controller board 42 via thetransceiver 41, commanding the controller board 42 to activate thejamming device 43. This is done in order to simulate un-jamming/clearingof the non-lethal, air-gun training weapon. Once activated, the jammingdevice 43 prevents the user from firing any further simulated laserrounds until a predetermined procedure has been carried out. Uponperforming the predetermined procedure, the jamming device 43 isdeactivated and the user is able to once again fire the laser assembly3, resuming simulated fire. The external computer system may alsorandomly send a signal to activate the jamming device 43 in order tosimulate the random jamming of a real firearm. In all embodiments of thepresent invention, the controller board 42 is capable of recording thenumber of simulated laser rounds fired and/or determining when toactivate the jamming device 43.

In reference to FIG. 2 and FIG. 4, the jamming device 43 comprises ajamming rod 431 and an actuating mechanism 432. The actuating mechanism432 is positioned within the magazine casing 21, while the jamming rod431 is bistably positioned through the magazine casing 21. When thejamming device 43 is deactivated the jamming rod 431 is positionedwithin the magazine casing 21. The jamming rod 431 is operativelycoupled to the actuating mechanism 432, such that when the jammingdevice 43 is activated the jamming rod 431 traverses out of the magazinecasing 21 and prevents the non-lethal, air-gun training weapon frombeing fired. In the preferred embodiment of the present invention, theactuating mechanism 432 comprises a solenoid, a solenoid arm, and amount block. The solenoid arm is connected to the mount block andslidably attached to the solenoid. The jamming rod 431 has a notched endthat is positioned in the mount block. A spring pin traverses throughthe mount block into the notched end of the jamming rod 431 and holdsthe jamming rod 431 in the deactivated position. When the externalcomputer system transmits a command to jam the non-lethal, air-guntraining weapon via the transceiver 41, the controller board 42 sends anelectric current through the solenoid, which in turn causes the solenoidarm and mount block to move. Movement of the mount block disengages thenotched end of the jamming rod 431 form the spring pin. A springconnected to the jamming rod 431 then forces the jamming rod 431 totraverse out of the magazine casing 21 into the receiver 11 and intobolt chamber 14. While positioned in the bolt chamber 14, the jammingrod 431 engages the bolt 13, preventing the bolt 13 from returning tothe unfired position. In this state, the bolt 13 prevents the hammer 162from engaging the gas release pin 163, thus locking the firing mechanism16 and preventing the non-lethal, air-gun training weapon from beingfired. In order to deactivate the jamming device 43, the jamming rod 431must be manually reset. The jamming rod 431 is reset by removing themagazine 2 from the air-gun 1 and pressing the jamming rod 431 back intothe magazine casing 21. When the jamming rod 431 is pushed back into themagazine casing 21, a spring under the mount block raises the mountblock such that notched end of the jamming rod 431 once again engagesthe spring pin.

In an alternative embodiment of the present invention, the actuatingmechanism 432 is again a solenoid. The jamming rod 431 is directlyattached to the solenoid such that linear motion of the jamming rod 431is directly controlled by the solenoid. When the external computersystem transmits a command to jam the non-lethal, air-gun trainingweapon via the transceiver 41, the controller board 42 sends an electriccurrent through the solenoid, which in turn causes the jamming rod 431to traverse out through the magazine casing 21. When the externalcomputer system transmits a command to un-jam the non-lethal, air-guntraining weapon, the controller board 42 removes the current to thesolenoid, which in turn allows the jamming rod 431 to slide back intothe magazine casing 21, thus allowing the user to fire the non-lethal,air-gun training weapon again.

In another alternative embodiment of the present invention, theactuating mechanism 432 is a motor. The jamming rod 431 is operativelycoupled to the motor in order to control the position of the jamming rod431. When the external computer system transmits a command to jam thenon-lethal, air-gun training weapon via the transceiver 41, thecontroller board 42 sends an electric current through the motor, whichin turn causes the jamming rod 431 to traverse out through the magazinecasing 21. When the external computer system transmits a command toun-jam the non-lethal, air-gun training weapon, the controller board 42reverses the current flow through the motor, which in turn pulls thejamming rod 431 back into the magazine casing 21, thus allowing the userto fire the non-lethal, air-gun training weapon again.

In yet another alternative embodiment of the present invention, thejamming rod 431 engages the gas release pin 163 instead of the bolt 13.When activated, the jamming rod 431 traverses out of the magazine casing21 into the receiver 11. The jamming rod 431 then engages the gasrelease pin 163, such that the gas release pin 163 is unable to engagethe gas release valve 23. This in turn prevents compressed gas frombeing released from the gas container 22 and thus the non-lethal,air-gun training weapon from being fired. It is also possible in otherembodiments for the jamming rod 431 to engage the gas release valve 23,such that compressed gas cannot be released from the gas container 22.

In reference to FIG. 5, the laser assembly 3 is positioned within theair-gun 1 and comprises a laser housing 31, a diode aperture 33, and alaser diode 32. In the preferred embodiment of the present invention,the laser assembly 3 is positioned into the barrel 12 of the air-gun 1adjacent to the bolt chamber 14. The laser assembly 3 may be fullypositioned within the barrel 12 or partially positioned within both thebarrel 12 and the bolt chamber 14. It is also possible for the laserassembly 3 to be fully positioned within the bolt chamber 14 adjacent tothe barrel 12. The laser housing 31 is a thin walled cylindricalstructure that is appropriately sized to be positioned within theair-gun 1. The laser housing 31 may be permanently connected to theair-gun 1 or removably attached to the air-gun 1, such that the laserassembly 3 may be replaced or maintained. The laser aperture is a smallhole that traverses into the end of the laser housing 31 that isdirected away from the bolt chamber 14. The laser diode 32 is positionedwithin the laser housing 31 adjacent to the diode aperture 33, such thatlight emitted from the laser diode 32 is directed out of the laserhousing 31 through the diode aperture 33 and out of the air-gun 1through the barrel 12. In the preferred embodiment of the presentinvention, the laser diode 32 is a light emitting diode, however, anyother type of light source may be used. The light emitted from the laserdiode 32 may or may not be visible to the human eye under normalconditions. For example, the type of light that may be emitted includes,but is not limited to, light waves in the visible, infrared, ornear-infrared spectrum.

In the preferred embodiment of the present invention, the laser diode 32is electrically connected to the battery 45, as depicted in FIG. 12.Electrical wire connects the battery 45 to a pair of leads on theoutside of the magazine 2. Similarly, electrical wire connects the laserassembly 3 to a pair of leads in the receiver 11. When the magazine 2 isattached to the air-gun 1, the pair of leads on the magazine 2 engagesthe pair of leads in the receiver 11. This acts to form a circuitbetween the battery 45 and the laser assembly 3. When the bolt sensor 44detects that a simulated laser round has been fired (i.e. detects thatthe bolt 13 has cycled), the controller board 42 allows current to flowthrough the circuit, thus illuminating the laser diode 32. In this way,the laser assembly 3 is able to simulate any type of weapon firing mode(i.e. semi-automatic, burst, fully automatic). Because the path of thelight emitted from the laser diode 32 is unimpeded, the laser assembly 3is able to emit light in a straight line and thus simulate the path thata live round would follow if fired from a real firearm. The lightemitted from the laser diode 32 can be tracked using photo-sensors,electro-optical sensors or any other light detection methods. Sensorscan be positioned on specific targets or assembled as an entire screenor dome structure. Activation of sensors is recorded by an externalcomputer system and used to determine if the user has successfully hithis or her targets.

In reference to FIG. 10, in an alternative embodiment of the presentinvention, the laser assembly 3 further comprises a pressure switch 34and a laser battery 35. The laser battery 35 is positioned within thelaser housing 31 in between the laser diode 32 and the pressure switch34. Instead of being electrically connected to the battery 45, the laserdiode 32 and the pressure switch 34 are electrically connected to thelaser battery 35, as depicted in FIG. 14. The electrical connection ofthe laser diode 32, pressure switch 34, and laser battery 35 forms anormally open circuit. Activation of the pressure switch 34 by thecompressed gas closes the normally open circuit and thus allows currentto flow through the laser diode 32.

In reference to FIG. 8-9, the pressure switch 34 is adjacently connectedto the laser housing 31 opposite the diode aperture 33. The pressureswitch 34 is actuated by the sudden pressure change in the bolt chamber14, which is generated by the discharge of compressed gas from the gascontainer 22 upon the trigger 161 being pulled. While in someembodiments the pressure switch 34 of the laser assembly 3 ispneumatically operated, it is also possible for the pressure switch 34to be mechanically operated. The pressure switch 34 traverses into thelaser housing 31 and is electrically coupled to the laser diode 32, suchthat the laser diode 32 is turned on and off in order to simulategunfire when the pressure switch 34 is activated or deactivated,respectively. The pressure switch 34 allows the laser assembly 3 to beactivated to simulate any type of weapon firing mode (i.e.semi-automatic, burst, fully automatic). When the pressure switch 34 isactivated, light is emitted from the laser diode 32 out of the barrel 12of the air-gun 1.

Although the invention has been explained in relation to its preferredembodiment, it is to be understood that many other possiblemodifications and variations can be made without departing from thespirit and scope of the invention as hereinafter claimed.

What is claimed is:
 1. A non-lethal, air-gun training weapon comprises:an air-gun; a magazine; a laser assembly; an electromechanical assembly;the air-gun comprises a receiver, a barrel, a bolt, a bolt chamber, agas channel, and a firing mechanism; the magazine comprises a magazinecasing, a gas container, a gas release valve, and a gas release vent;the laser assembly comprises a laser housing, a laser diode, and a diodeaperture; the electromechanical assembly comprises a transceiver, acontroller board, a jamming device, a bolt sensor, and a battery; thefiring mechanism being positioned within the receiver; the barrel beingadjacently connected to the receiver; the barrel being concentric withthe bolt chamber; the bolt chamber traversing into the receiver; thebolt being slidably positioned within the bolt chamber; the magazinecasing being attached to the receiver; the gas channel traversing intothe receiver and into the bolt chamber; and the gas container beingpneumatically coupled to both the laser assembly and the bolt throughthe gas channel and the bolt chamber.
 2. The non-lethal, air-guntraining weapon as claimed in claim 1 comprises: the laser assemblybeing positioned into the barrel adjacent to the bolt chamber; the diodeaperture traversing into the laser housing; and the laser diode beingpositioned within the laser housing adjacent to the diode aperture. 3.The non-lethal, air-gun training weapon as claimed in claim 1 comprises:the gas container being positioned within the magazine casing; the gasrelease valve being positioned into the magazine casing; and the gascontainer being in fluid communication with the gas channel through thegas release valve.
 4. The non-lethal, air-gun training weapon as claimedin claim 1 comprises: the magazine further comprises a gas refill valve;the gas refill valve being positioned into the magazine casing; and thegas refill valve being in fluid communication with the gas container. 5.The non-lethal, air-gun training weapon as claimed in claim 1 comprises:the transceiver, the controller board, and the battery being positionedwithin the magazine casing; the bolt sensor being positioned into themagazine casing; the transceiver, the controller board, the jammingdevice, and the bolt sensor being electrically connected to the battery;and the transceiver, the jamming device, and the bolt sensor beingelectronically connected to the controller board.
 6. The non-lethal,air-gun training weapon as claimed in claim 1 comprises: the laser diodebeing electrically connected to the battery.
 7. The non-lethal, air-guntraining weapon as claimed in claim 1 comprises: the laser assemblyfurther comprises a pressure switch and a laser battery; the laserbattery being positioned within the laser housing; the pressure switchbeing adjacently connected to the battery housing opposite the diodeaperture; the pressure switch traversing into the laser housing; and thelaser diode and the pressure switch being electrically connected to thelaser battery.
 8. The non-lethal, air-gun training weapon as claimed inclaim 1 comprises: the jamming device comprises a jamming rod and anactuating mechanism; the actuating mechanism being positioned within themagazine casing; the jamming rod being bistably positioned through themagazine casing; and the jamming rod being operatively coupled to theactuating mechanism.
 9. The non-lethal, air-gun training weapon asclaimed in claim 8 comprises: the jamming rod traversing out of themagazine casing into the receiver and the bolt chamber; and the jammingrod engaging the bolt.
 10. The non-lethal, air-gun training weapon asclaimed in claim 1 comprises: the firing mechanism comprises a trigger,a hammer, and a gas release pin; the gas release pin being slidablypositioned within the receiver; the hammer being mechanically coupled tothe trigger; and the trigger being operatively coupled to the gasrelease pin through the hammer.
 11. The non-lethal, air-gun trainingweapon as claimed in claim 10 comprises: the gas release pin engagingthe gas release valve.
 12. A non-lethal, air-gun training weaponcomprises: an air-gun; a magazine; a laser assembly; anelectromechanical assembly; the air-gun comprises a receiver, a barrel,a bolt, a bolt chamber, a gas channel, and a firing mechanism; themagazine comprises a magazine casing, a gas container, a gas releasevalve, and a gas release vent; the laser assembly comprises a laserhousing, a laser diode, and a diode aperture; the electromechanicalassembly comprises a transceiver, a controller board, a jamming device,a bolt sensor and a battery; the firing mechanism comprises a trigger, ahammer, and a gas release pin; the jamming device comprises a jammingrod and an actuating mechanism; the firing mechanism being positionedwithin the receiver; the barrel being adjacently connected to thereceiver; the barrel being concentric with the bolt chamber; the laserassembly being positioned into the barrel adjacent to the bolt chamber;the bolt chamber traversing into the receiver; the bolt being slidablypositioned within the bolt chamber; the magazine casing being attachedto the receiver; the gas channel traversing into the receiver and intothe bolt chamber; the gas container being pneumatically coupled to boththe laser assembly and the bolt through the gas channel and the boltchamber; the transceiver, the controller board, the jamming device, andthe bolt sensor being electrically connected to the battery; thetransceiver, the jamming device, and the bolt sensor beingelectronically connected to the controller board; the diode aperturetraversing into the laser housing; the laser diode being positionedwithin the laser housing adjacent to the diode aperture; the actuatingmechanism being positioned within the magazine casing; the jamming rodbeing bistably positioned through the magazine casing; the jamming rodbeing operatively coupled to the actuating mechanism; the gas releasepin being slidably positioned within the receiver; the hammer beingmechanically coupled to the trigger; the trigger being operativelycoupled to the gas release pin through the hammer; the gas containerbeing positioned within the magazine casing; the gas release valve beingpositioned into the magazine casing; and the gas container being influid communication with the gas channel through the gas release valve.13. The non-lethal, air-gun training weapon as claimed in claim 12comprises: the magazine further comprises a gas refill valve; the gasrefill valve being positioned into the magazine casing; and the gasrefill valve being in fluid communication with the gas container. 14.The non-lethal, air-gun training weapon as claimed in claim 12comprises: the laser diode being electrically connected to the battery.15. The non-lethal, air-gun training weapon as claimed in claim 12comprises: the laser assembly further comprises a pressure switch and alaser battery; the laser battery being positioned within the laserhousing; the pressure switch being adjacently connected to the batteryhousing opposite the diode aperture; the pressure switch traversing intothe laser housing; and the laser diode and the pressure switch beingelectrically connected to the laser battery.
 16. The non-lethal, air-guntraining weapon as claimed in claim 12 comprises: the jamming rodtraversing out of the magazine casing into the receiver and the boltchamber; and the jamming rod engaging the bolt.
 17. The non-lethal,air-gun training weapon as claimed in claim 12 comprises: the gasrelease pin engaging the gas release valve.